Li, et al.
               https://doi.org/10.1002/smll.201805510              Activity  Post-Myocardial  Infarction  is Related  to  Reduced
           65.  Wang X, Ao Q, Tian X, et al., 2017, Gelatin-Based Hydrogels   Mortality: Results From the SWEDEHEART Registry. J Am
               for Organ 3D Bioprinting. Polymers, 9:401.          Heart Assoc, 7:e010108.
               https://doi.org/10.3390/polym9090401                https://doi.org/10.1161/JAHA.118.010108
           66.  Wang X, 2019, Advanced Polymers for Three-Dimensional   77.  Li J, Cai Z, Cheng J,  et al., 2020, Characterization  of a
               (3D) Organ Bioprinting. Micromachines, 10:814.      Heparinized  Decellularized  Scaffold  and  its  Effects  on
               https://doi.org/10.3390/mi10120814                  Mechanical and Structural Properties. J Biomater Sci Polym
           67.  Suri  S, Han  LH,  Zhang  W,  et  al.,  2011,  Solid  Freeform   Ed, 31:999–1023.
               Fabrication  of  Designer  Scaffolds  of  Hyaluronic  Acid  for      https://doi.org/10.1080/09205063.2020.1736741
               Nerve Tissue Engineering. Biomed Microdevices, 13:983–93.  78.  Gao RL, Zhang S, Wang ZW, et al., 2019, The Development
               https://doi.org/10.1007/s10544-011-9568-9           of Cardiology in China in 70 Years since the Founding of
           68.  Lin H, Zhang D, Alexander PG,  et al.,  2013, Application   the People’s Republic  of China (Excerpts).  Chin J Card
               of  Visible  Light-Based  Projection  Stereolithography  for   Arrhythm, 23:459–60.
               Live  Cell-scaffold  Fabrication  with  Designed Architecture.   79.  Mironov V, Boland T, Trusk T, et al., 2003, Organ Printing:
               Biomaterials, 34:331–9.                             Computer-Aided Jet-Based  3D  Tissue Engineering.  Trends
               https://doi.org/10.1016/j.biomaterials.2012.09.048  Biotechnol, 21:157–61.
           69.  Laschke MW, Rücker M, Jensen G, et al., 2008, Incorporation      https://doi.org/10.1016/S0167-7799(03)00033-7
               of  Growth  Factor  Containing  Matrigel  Promotes  80.  Nakamura  M,  Kobayashi  A,  Takagi  F,  et al., 2005,
               Vascularization of Porous PLGA Scaffolds. J Biomed Mater   Biocompatible  Inkjet  Printing  Technique  for  Designed
               Res A, 85:397–407.                                  Seeding of Individual Living Cells. Tissue Eng, 11:1658–66.
               https://doi.org/10.1002/jbm.a.31503             81.  Leong  KF,  Cheah  CM,  Chua  CK,  2003,  Solid  Freeform
           70.  Hinton  TJ,  Jallerat  Q,  Palchesko  RN,  et al.,  2015, Three-  Fabrication of Three-Dimensional Scaffolds for Engineering
               Dimensional Printing of Complex Biological Structures by   Replacement Tissues and Organs. Biomaterials, 24:2363–78.
               Freeform Reversible Embedding of Suspended Hydrogels.   82.  Noor N, Shapira  A, Edri R,  et al., 2019, 3D Printing of
               Sci Adv, 1:e1500758.                                Personalized  Thick  and  Perfusable  Cardiac  Patches  and
               https://doi.org/10.1126/sciadv.1500758              Hearts. Adv Sci, 6:1900344.
           71.  Golden  AP,  Tien  J,  2007,  Fabrication  of  Microfluidic   83.  Lee A, Hudson AR, Shiwarski DJ, et al., 2019, 3D Bioprinting
               Hydrogels  Using  Molded  Gelatin  as  a  Sacrificial  Element.   of Collagen to Rebuild  Components of the Human Heart.
               Lab Chip, 7:720–5.                                  Science, 365:482–7.
               https://doi.org/10.1039/b618409j                    https://doi.org/10.1126/science.aav9051
           72.  Lee VK,  Kim DY, Ngo H,  et al., 2014, Creating Perfused   84.  Duan B, Kapetanovic E, Hockaday LA, et al., 2014, Three-
               Functional  Vascular  Channels  using  3D Bio-Printing   Dimensional  Printed  Trileaflet  Valve  Conduits  Using
               Technology. Biomaterials, 35:8092–102.              Biological  Hydrogels and Human  Valve Interstitial  Cells.
               https://doi.org/10.1016/j.biomaterials.2014.05.083  Acta Biomater, 10:1836–46.
           73.  Zhao L, Lee VK, Yoo SS, et al., 2012, The Integration of      https://doi.org/10.1016/j.actbio.2013.12.005
               3-D Cell Printing and Mesoscopic Fluorescence Molecular   85.  Hockaday LA, Duan B, Kang KH, et al., 2014, 3D Printed
               Tomography of Vascular Constructs Within Thick Hydrogel   Hydrogel Technologies for Tissue Engineered Heart Valves.
               Scaffolds. Biomaterials, 33:5325–32.                3D Print Addit Manuf, 1:122–36.
               https://doi.org/10.1016/j.biomaterials.2012.04.004  86.  Grigoryan  B,  Paulsen  SJ, Corbett  DC,  et  al.,  2019,
           74.  Novosel EC, Kleinhans C, Kluger PJ, 2011, Vascularization   Multivascular  Networks  and  Functional  Intravascular
               is the Key Challenge in Tissue Engineering. Adv Drug Deliv   Topologies within Biocompatible Hydrogels.  Science,
               Rev, 63:300–11.                                     364:458–64.
               https://doi.org/10.1016/j.addr.2011.03.004          https://doi.org/10.1126/science.aav9750
           75.  Lei M, Wang X, 2015, Uterus Bioprinting. In: Wang X, editor.   87.  Yan Y, Wang X, Pan Y, et al., 2005, Fabrication of Viable
               Organ Manufacturing. Hauppauge, NY, USA: Nova Science   Tissue-Engineered Constructs with 3D  Cell-Assembly
               Publishers Inc., p335–55.                           Technique. Biomaterials, 26:5864–71.
           76.  Ekblom O, Ek A, Cider Å, et al., 2018, Increased Physical      https://doi.org/10.1016/j.biomaterials.2005.02.027

                                       International Journal of Bioprinting (2022)–Volume 8, Issue 3       251